Composition for air polishing

ABSTRACT

A composition for air polishing the surface of hard dental tissue includes an abrasive first powder suitable for polishing hard dental tissue; a second powder of a gelling agent; and a third powder of a dental treatment agent.

BACKGROUND OF THE INVENTION

The invention relates to a novel composition for air polishing thesurface of hard dental tissue and to its use in an air polishing method.

Powders for dental air polishing are generally based on glycine, calciumcarbonate, or sodium bicarbonate. Known powders include in particular aglycine-based powder developed by the supplier 3M ESPE and availableunder the reference “Clinpro Prophy Powder” for subgingival use, and asodium bicarbonate-based powder sold by the supplier Satelec under thereference “Air-n-go Classic” for supragingival use.

Nevertheless, there exists a need to improve existing air polishingtreatments so as to functionalize such treatments further withoutthereby leading to a significant lengthening of treatment time.

There exists in particular a need to have improved air polishingtreatment available that also makes it possible to perform effectivetherapeutic action on the treated tooth without that leading to asignificant lengthening of treatment time.

OBJECT AND SUMMARY OF THE INVENTION

To this end, in a first aspect, the invention provides a composition forair polishing the surface of hard dental tissue, the compositioncomprising at least:

-   -   an abrasive first powder for polishing hard dental tissue;    -   a second powder of a gelling agent; and    -   a third powder of a dental treatment agent.

The term “hard dental tissue” is used to cover enamel, dentine, andcement.

The composition of the invention is remarkable in that it serves firstlyto perform air polishing treatment of hard dental tissue, and secondly,because of the presence of the gelling second powder, to form an activegel containing the treatment agent and enabling prolonged action to beperformed on the treated tooth, in particular therapeutic action. Moreprecisely, and as described in greater detail below, the composition ofthe invention, when sprayed by the air polisher at a relatively shortdistance from the treated tissue, serves to perform the desiredpolishing, and when the air polisher is moved further away from thetreated tooth, it serves to form the active gel. Thus, by means of thecomposition of the invention, it is possible with a single compositionand a single air polishing tool to perform two successive actions, thefirst being polishing hard dental tissue and the second being treatingdental tissue with a treatment agent present in the active gel that isformed. The active gel that is formed can serve to treat hard dentaltissue and/or soft dental tissue. The formation of the active gel isadvantageous to enable the dental treatment agent to act over arelatively long duration. The composition of the invention thusadvantageously makes it possible to functionalize conventional dentalair polishing treatments to a greater extent by associating it with anytype of dental treatment that can be performed by depositing gel, butwithout that making the treatment more complex or lengthening the timerequired for the treatment.

The gelling agent may be an organic compound. In a variant, the gellingagent may be an inorganic compound.

In an embodiment, the gelling agent may be selected from: poloxamers,carbomers, polyvinylpyrrolidones, polyethylene glycol, polyvinylalcohol, seaweed extract, fruit extracts, gelatin, plant seed gums,plant exudates, cellulose or cellulose derivatives, microorganismexudates, fatty acid esters of polyoxyethylene, fatty acid esters ofpolyoxyethylenesorbitan, clays, and mixtures thereof.

The poloxamer type gelling agent may be a copolymer having polyethyleneglycol (PEG)-polypropylene glycol (PPG)-polyethylene glycol blocks.

By way of example, the gelling agent of the seaweed extract type may beselected from: agar-agar, carrageenans, alginates, alginic acid, orfurcellerans. By way of example, the alginate type gelling agent may beselected from: sodium alginate, potassium alginate, ammonium alginate,calcium alginate, or propane-1,2-diol alginate.

By way of example, the fruit extract type gelling agent may be pectin.

By way of example, the plant seed gum type gelling agent may be selectedfrom: carob gum, guar gum, or oat gum.

By way of example, the plant exudate type gelling agent may be selectedfrom: gum arabic, karaya gum, or gum tragacanth.

By way of example, the cellulose derivative type gelling agent may beselected from: methyl cellulose, ethyl cellulose, hydroxpyropylcellulose, hydroxypropylmethyl cellulose, methylethyl cellulose, orcarboxymethyl cellulose.

By way of example, the microorganism exudate type gelling agent may beselected from: xanthan gum or gellan gum.

By way of example, the fatty acid ester of polyoxyethylene type gellingagent may be polyoxyethylene stearate.

By way of example, the fatty acid ester of polyoxyethylenesorbitan typegelling agent may be selected from: polyoxyethylene-20-sorbitanmonolaurate, polyoxyethylene-20-sorbitan monooleate,polyoxyethylene-20-sorbitan monopalmitate, polyoxyethylene-20-sorbitanmonostearate, or polyoxyethylene-20-sorbitan tristearate.

By way of example, the clay type gelling agent may be selected from:kaolin, magnesium aluminosilicates, bentonites, or hectorite.

Preferably, the gelling agent is selected from: poloxamers,hydroxypropylmethyl cellulose, carrageenans, and mixtures thereof.

In an embodiment, the second powder may be present in the composition ata content by weight lying in the range 0.5% to 80%, e.g. in the range0.5% to 50%.

In an embodiment, the mean size of the grains of the second powder maylie in the range 0.5 micrometers (μm) to 400 μm.

Unless specified to the contrary, the term “mean size” is used todesignate the dimension given by the half population statistical grainsize distribution, known as D50.

The abrasive particles of the first powder may present hardness on theMohs scale greater than or equal to 1, preferably lying in the range 1to 5, more preferably in the range 1 to 3.

In an embodiment, the first powder may comprise sodium bicarbonate,calcium carbonate, glycine, a silicate, silica, silicon hydroxide,silicon carbide, powdered pumice stone, diamond powder, aluminum oxide,aluminum hydroxide, or a mixture of these compounds.

The first powder may be a powder of organic particles, which particlesmay be water-soluble. Preferably, the first powder may comprise sodiumbicarbonate, calcium carbonate, glycine, or a mixture of such compounds.

In an embodiment, the first powder may be present in the composition ata content by weight lying in the range 15% to 98%, e.g. in the range 50%to 98%.

In an embodiment, the mean grain size of the first powder may lie in therange 5 μm to 500 μm.

Preferably, the dental treatment agent may be a therapeutic agent.

The therapeutic agent may be an antiseptic agent, an anti-inflammatoryagent, an anesthetic agent, a desensitizing agent, a remineralizingagent, an astringent agent, or a mixture of such agents.

Preferably, the desensitizing agent may be selected from sodiumfluoride, potassium nitrate, oxalic acid, tin fluoride, or mixturesthereof.

Preferably, the remineralizing agent may be selected from calciumphosphate, calcium chloride, calcium nitrate, sodium phosphate,tricalcium phosphate, tricalcium silicate, hydroxyapatite, silicateglasses, or mixtures thereof.

Preferably, the antiseptic agent may be selected from chlorhexidinechlorhydrate, chlorhexidine dichlorhydrate, chlorhexidine gluconate,chlorhexidine digluconate, sodium hypochlorite, quaternary ammoniums,iodine derivatives, and mixtures thereof.

Preferably, the anti-inflammatory agent may be selected from butoforme,prednisolone acetate, □-glycrrhetinic acid, a non-steroidalanti-inflammatory agent, and mixtures thereof.

Preferably, the anesthetic agent may be selected from lidocainechlorhydrate.

Preferably, the astringent agent may be selected from aluminum chloride.

In a variant, the dental treatment agent may be a coloring agent, e.g. afluorescent coloring agent. By way of example, the coloring agent may bean optical whitener. By way of example, the dental treatment agent maythus be selected from sodium fluorescein, brilliant blue, and mixturesthereof.

By way of example, the third powder may present a mean grain size lyingin the range 0.5 μm to 500 μm, e.g. lying in the range 0.5 μm to 200 μm.

Advantageously, the composition may further comprise an anti-cakingagent. By way of example, the anti-caking agent may be selected fromanhydrous colloidal silica, hydrophobic pyrogenic silica, tricalciumphosphate, and mixtures thereof. The anti-caking agent may be in theform of a powder, with the grains of this powder presenting a mean grainsize lying in the range 0.5 μm to 200 μm, for example.

Preferably, the composition may comprise:

-   -   the first powder at a content by weight lying in the range 15%        to 98%;    -   the second powder at a content by weight lying in the range 0.5%        to 80%;    -   the third powder at a content by weight lying in the range        0.005% to 25%, e.g. lying in the range 0.005% to 20%; and    -   an anti-caking agent at a content by weight lying in the range        0.05% to 10%.

In an embodiment, the composition may comprise:

-   -   the first powder at a content by weight lying in the range 70%        to 98%;    -   the second powder at a content by weight lying in the range 0.5%        to 20%;    -   the third powder at a content by weight lying in the range        0.005% to 25%, e.g. in the range 0.005% to 20%; and    -   an anti-caking agent at a content by weight lying in the range        0.05% to 10%.

Such a formulation example is particularly suitable for supragingivaltreatment.

In an embodiment, the composition may comprise:

-   -   the first powder at a content by weight lying in the range 15%        to 70%;    -   the second powder at a content by weight lying in the range 20%        to 80%; e.g. in the range 40% to 80%;    -   the third powder at a content by weight lying in the range        0.005% to 25%, e.g. in the range 0.005% to 20%; and    -   an anti-caking agent at a content by weight lying in the range        0.05% to 10%.

Such a formulation example is particularly suitable for subgingivaltreatment.

The present invention also provides a dental air polishing tool having anozzle and a tank containing a composition as described above, thenozzle being configured to spray said composition under pressuresurrounded by a jet of liquid.

The present invention also provides a composition as described above inwhich the treatment agent is a therapeutic agent for use as medicationin the therapeutic treatment of dental tissue.

Under such circumstances, the therapeutic treatment may comprise atleast:

-   -   air polishing hard dental tissue, during which the composition        surrounded by a jet of liquid is sprayed under pressure against        said tissue through a nozzle of an air polishing tool, the        nozzle being situated at a first distance from the treated tooth        during air polishing;    -   after air polishing, placing the nozzle at a second distance        from the treated tooth that is greater than the first distance;        and    -   forming an active gel including the therapeutic agent on the        treated tooth by spraying the composition surrounded by the        liquid jet under pressure through the nozzle positioned in this        way at the second distance from the treated tooth.

BRIEF DESCRIPTION OF THE DRAWINGS

Other characteristics and advantages of the invention appear from thefollowing description of particular embodiments of the invention givenas non-limiting examples and made with reference to the accompanyingdrawings, in which:

FIGS. 1 and 2 are diagrams showing the conduct of an implementation ofthe supragingival dental treatment method using a composition of theinvention;

FIG. 3 shows a tooth treated by the method shown in FIGS. 1 and 2;

FIGS. 4 and 5 are diagrams showing the conduct of an implementation ofthe subgingival treatment method using a composition of the invention;

FIG. 6 shows a tooth treated by the method shown in FIGS. 4 and 5; and

FIG. 7 is a photograph of a substrate treated by an example of acomposition of the invention showing both the polishing that isperformed and also the formation of the gel.

DETAILED DESCRIPTION OF IMPLEMENTATIONS

FIG. 1 shows the first step of a method of the invention during which atooth D is subjected to air polishing using a composition of theinvention. In the example shown, the tooth D is an incisor. Naturally,it would not go beyond the ambit of the invention to treat some othertype of tooth. The tooth D for treatment presents a plurality of cracksF in its surface, which cracks are covered in a deposit of a substance Sthat is to be removed, such as a deposit of dental plaque.

During this first step, a dental air polishing tool 10 is used to spraythe air polishing composition 1 under pressure through the nozzle 11 ofthe tool 10. More precisely, the jet of composition 1 and a cone 15 ofliquid surrounding the jet 1 are sprayed through the nozzle 11. By wayof example, the liquid 15 may be water. An example of an air polishingtool 10 suitable for use is the air polisher sold under the referenceAir-N-Go□ by the supplier Acetone. As described above, the spraycomposition 1 comprises at least a mixture of the following threeingredients: a first powder of abrasive particles; a second powder of agelling agent; and a third powder of the dental treatment agent. Thecomposition 1 may be a powder. The first powder may be different fromthe second powder. The first powder may be different from the thirdpowder. The second powder may be different from the third powder. In avariant, the second powder and the third powder may be identical. Thisis possible, for example, when the gelling agent used is a poloxamer,which may have an antiseptic effect and thus constitute simultaneouslythe gelling agent and the therapeutic agent. As described in detailbelow, the gelling agent is configured to form a gel on the treatedtooth while it is mixing with the liquid sprayed by the air polishingtool 10. Advantageously, the composition 1 may also comprise ananti-caking agent, as described above.

The impact of the spray composition 1 against the tooth D serves toclean the surface of the tooth D and to eliminate the deposit S. Duringthis first step, the nozzle 11 is situated at a relatively shortdistance d₁ from the tooth D for treatment. As a result, the jet ofcomposition 1 impacts against the tooth T with relatively high pressure,thereby eliminating the deposit S present on the tooth D. By way ofexample, the distance d₁ is less than or equal to 0.5 centimeters (cm).

Furthermore, during the final step and still because of this highpressure, the ingredients of the composition 1 do not become depositedon the tooth D for more than a few seconds, and they are removed fromthe surface of the tooth D together with the substance S immediatelyafter impact. By way of example, the treatment of a tooth during thisfirst step may last for at least one second, and may last for threeseconds, by way of example. Advantageously, the first powder maycomprise at least one of the following compounds: sodium bicarbonate,calcium carbonate, glycine, a silicate, silica, silicon hydroxide,silicon carbide, powdered pumice stone, diamond powder, aluminum oxide,aluminum hydroxide, or a mixture of these compounds. Advantageously, thefirst powder may comprise at least one of the following compounds:sodium bicarbonate, calcium carbonate, glycine, or a mixture of suchcompounds.

Once the polishing step has been performed, the user moves the nozzle 11a little away from the tooth D that has been cleaned in this way inorder to position it at a distance d₂ and form an active gel 20 on thetooth D. In the example shown in FIGS. 1 to 3, the treated portion ofthe tooth is situated above the gum: this is a supragingival dentaltreatment method. By way of example, the distance d₂ is greater than orequal to 0.6 cm, e.g. 1 cm. The performance of this step is shown inFIG. 2. The active gel 20 is formed as a result of mixing between thesecond powder and the water sprayed by the tool 10. This gel 20 formsonly when the nozzle 11 is relatively far away from the tooth D, sincethe impact pressure of the composition 1 sprayed against the tooth D isthen reduced, thereby enabling the ingredients of the composition 1 tobecome deposited on the tooth D and enabling the gelling agent to formthe gel by mixing with the liquid. Advantageously, the gelling agent maybe selected from: poloxamers, hydroxypropylmethyl cellulose, methylcellulose, carrageenans, and mixtures thereof. The active gel 20 that isformed contains the dental treatment agent initially present in thecomposition 1. The dental treatment agent may be a therapeutic agent asdescribed above. The active gel 20 serves to fill the cracks F presentin the surface of the tooth D and to perform dental treatment over arelatively long duration, e.g. at least one minute, e.g. severalminutes. The active gel 20 can thus make it possible to perform at leastone of the following actions: remineralization, desensitization, ordisinfection of the treated dental tissue. The active gel 20 isconfigured to remain in contact with the tooth D in order to perform thelooked-for dental treatment. Advantageously, the active gel 20 may bewater-soluble in order to dissolve progressively in the patient's mouthonce the dental treatment has been performed.

The treated tooth D′ as obtained after the first and second steps isshown in FIG. 3. The cracks F that were initially present in thenon-treated tooth D may be filled as a result of the treatment of theinvention, as shown.

FIGS. 4 to 6 show the treatment of a tooth D suffering fromperiodontitis. This tooth D is a molar in the example shown. Airpolishing is initially performed using the tool 10 with a composition asdescribed above in order to eliminate the substance S present at thesurface of the tooth D (see FIG. 4). Once cleaning has been done, thenozzle 11 is then moved further away from the treated tooth in order toform an active gel 20 thereon (see FIG. 5). The active gel 20 is formedin particular in the periodontal pocket P present between the retractedgum G and the tooth D. The treatment that is performed serves to treatthe periodontitis and enables the gum to restore itself. The gel 20 thatis formed may also include a remineralizing agent in order to restorethe enamel of the treated tooth. After treatment, a healthy gum G′ isobtained supporting the treated tooth D′. For this type of subgingivaltreatment, it is advantageously possible to use a composition presentinga large quantity of abrasive particles of weak abrasive power or a smallquantity of abrasive having strong abrasive power.

EXAMPLES

In the examples, all of the proportions are expressed as percentages byweight, unless specified to the contrary, temperature is measured indegrees Celsius (° C.), and pressure is taken to be equal to atmosphericpressure (1 bar), unless specified to the contrary.

Example 1

An air polishing composition was made having the composition set out inTable 1 below.

TABLE 1 Formulation % Sodium bicarbonate 81.50 Aerosil R972 4.00 Sodiumsaccharin 2.00 Sodium fluoride 0.50 Potassium nitrate 2.50 Calciumnitrate tetrahydrate 2.00 Sodium hydrogen phosphate dodecahydrate 2.5Poloxamer 5.00

The composition was prepared in the manner described below.

A first pre-mixture A was made by adding half of the quantity of sodiumbicarbonate and half of the quantity of Aerosil R972 to a mixturecomprising the calcium nitrate tetrahydrate and the sodium hydrogenphosphate dodecahydrate. The mixture was homogenized using a cube mixersold under the trademark Frogerais. The mixture was then screened at 200μm using a vibrating screen.

A second pre-mixture B was made by mixing the other half of the quantityof sodium bicarbonate, the other half of the quantity of Aerosil R972,the sodium saccharin, the sodium fluoride, the potassium nitrate, andthe poloxamer. The mixture was homogenized using a cube mixer sold underthe trademark Frogerais. The mixture was then screened at 200 μm with avibrating screen.

The pre-mixtures A and B were then homogenized in order to obtain thecomposition set out in Table 1 above.

The composition as obtained in this way was then fragmented and screenedat 200 μm respectively using a hammer mill sold by the supplierPoitemill Forplex and by a vibrating screen.

The resulting powder composition for air polishing presented good dryflow and a D50 mean grain size lying in the range 70 μm to 90 μm whenmeasured with a laser granulometer type instrument sold by the supplierMalvern.

When incorporated in a dental air polishing tool, the composition servesfirstly to perform supragingival polishing and then, by moving away thenozzle of the air polishing tool, to form a remineralizing anddesensitizing gel on the treated tooth. In this respect, FIG. 7 is aphotograph of a card substrate SU coated in a layer of black paint ontowhich the composition of Example 1 was sprayed by a dental air polishingtool. The zones Z₁ correspond to zones that were “treated” at shortrange. These zones Z₁ were polished without forming gel. It can be seenthat after the polishing formed in the zones Z₁, the coating of blackpaint was eliminated, thereby revealing the underlying substrate, whichappears white in the photograph of FIG. 7. The zones Z₂ correspond tozones that were initially polished, like the zones Z₁, and for which thenozzle of the air polishing tool was then moved away so as to form agel. These zones Z₂ appear gray in the photograph of FIG. 7 because ofthe formation of the gel.

Example 2

An air polishing composition was fabricated having the formulation setout in Table 2 below.

TABLE 2 Formulation % Calcium carbonate 20.00 Aerosil R972 1.00 Sodiumsaccharin 1.00 Chlorhexidine chlorhydrate 2.50 Potassium nitrate 2.50□-tricalcium phosphate 17.00 Carrageenan 56.00

The composition set out in Table 2 above was obtained by adding thefollowing to the calcium carbonate and in this order: sodium saccharin,chlorhexidine chlorhydrate, potassium nitrate, □-tricalcium phosphate,carrageenan gelling agent, and Aerosil R972.

The mixture was then homogenized using a mixer of the bin blender typesold by the supplier Servolift. The resulting composition was thenscreened with a vibrating screen.

The resulting composition presented mean grain size in the range 40 μmto 60 μm when measured using a “Mastersizer 2000” type lasergranulometer sold by the supplier Malvern.

The composition fabricated in that way is suitable for supragingival orsubgingival use for polishing and then forming a gel constituting anantiseptic “dressing” for treating the periodontal pocket.

Example 3

An air polishing composition was fabricated having the formulation setout in Table 3 below.

TABLE 3 Formulation % Glycine 60.00 Aerosil R972 2.00 Sodium saccharin2.00 Mint flavoring 0.50 Lidocaine chlorhydrate 2.50 Hydroxapatite 18.00Methocel E4M 15.00

This composition was fabricated by milling the glycine with a hammermill sold by the supplier Poitemill Forplex. Thereafter the followingwere added to the milled glycine and in this order: sodium saccharin,essential oil of peppermint, lidocaine chlorhydrate, hydroxapatite,Methocel E4M, and Aerosil R972. The composition was homogenized using aV mixer sold by the supplier Olsa and then screened at 300 μm with avibrating screen.

The resulting composition presented mean grain size lying in the range15 μm to 35 μm as measured with a “Mastersizer 2000” type lasergranulometer sold by the supplier Malvern.

The composition as fabricated in that way can be used, after forming theactive gel, to anesthetize soft dental tissue when applied in aperiodontal pocket while cleaning the pocket.

Example 4

An air polishing composition was fabricated having the formulation setout in Table 4 below.

TABLE 4 Formulation % Glycine 15.00 Aerosil R972 3.00 Sodium saccharin2.00 Aluminum chloride 10.00 Kaolin 27.70 Essential oil of lemon 0.30Methyl cellulose 42.00

A pre-mixture A was made by adding half of the quantity of glycine andhalf of the quantity of Aerosil R972 to the mixture of aluminum chlorideand kaolin. The mixture was homogenized using a cube mixer sold underthe trademark Frogerais and then screened at 200 μm with a vibratingscreen.

A second pre-mixture B was made by mixing the other half of the quantityof glycine, the sodium saccharin, the essential oil of lemon, the methylcellulose, and the other half of the quantity of Aerosil R972. Themixture was homogenized using a cube mixer sold by the supplierServolift and then screened at 200 μm using an oscillating grinderhaving the trademark Frewitt.

Thereafter, the pre-mixture A and the pre-mixture B were homogenized.The resulting composition was then fragmented and screened at 200 μmusing a cone mill sold by Frewitt in order to obtain the composition setout in Table 4 above. The composition represented good dry flow and D50mean grain size lying in the range 25 μm to 45 μm as measured with alaser granulometer type instrument sold by the supplier Malvern.

The composition as fabricated in that way can be used to performsubgingival polishing and subsequently, by moving away the nozzle of theair polisher, to form a hemostatic gel serving to keep the sulcus openafter rinsing the gel because of the treatment by aluminum chloride.

The term “lying in the range . . . to . . . ” should be understood asincluding the bounds.

The invention claimed is:
 1. A method of treating dental tissue using acomposition for air polishing a surface of hard dental tissue, thecomposition comprising at least: an abrasive first powder suitable forpolishing hard dental tissue, the first powder comprising sodiumbicarbonate, calcium carbonate, glycine, a silicate, silica, siliconhydroxide, silicon carbide, powdered pumice stone, diamond powder,aluminum oxide, aluminum hydroxide, or a mixture of these compounds, amean grain size of the first powder being in the range of 5 μm to 500μm; a second powder of a gelling agent comprising a poloxamer,hydroxypropylmethyl cellulose, methyl cellulose, a carrageenan, or amixture thereof; and a third powder of a dental treatment agent, thedental treatment agent comprising a therapeutic agent, a coloring agent,or a mixture thereof; wherein the method comprises at least: airpolishing the hard dental tissue during which the composition is sprayedagainst said tissue at a first distance from the tissue; and thenspraying the composition at a second distance from the tissue, thesecond distance being greater than the first distance, to form a gel onthe hard dental tissue and/or on soft dental tissue.
 2. The methodaccording to claim 1, the second powder being present in the compositionat a content by weight lying in a range of 0.5% to 80%.
 3. The methodaccording to claim 1, a mean size of the grains of the second powderlying in a range of 0.5 μm to 400 μm.
 4. The method according to claim1, the first powder comprising sodium bicarbonate, calcium carbonate,glycine, or a mixture of such compounds.
 5. The method according toclaim 1, the first powder comprising glycine and the second powdercomprising a poloxamer.
 6. The method according to claim 1, the firstpowder comprising sodium bicarbonate and the second powder comprising apoloxamer.
 7. The method according to claim 1, the first powder beingpresent in the composition at a content by weight lying in a range of15% to 98%.
 8. The method according to claim 1, the compositioncomprising: the first powder at a content by weight lying in a range 15%to 98%; the second powder at a content by weight lying in a range 0.5%to 80%; and the third powder at a content by weight lying in a range0.005% to 25%; and optionally, an anti-caking agent at a content byweight lying in a range 0.05% to 10%.
 9. The method according to claim8, the composition comprising: the first powder at a content by weightlying in the range of 70% to 98%; the second powder at a content byweight lying in the range of 0.5% to 20%; and the third powder at acontent by weight lying in the range of 0.005% to 25%; and optionally,an anti-caking agent at a content by weight lying in the range of 0.05%to 10%.
 10. The method according to claim 8, the composition comprising:the first powder at a content by weight lying in the range of 15% to70%; the second powder at a content by weight lying in the range of 20%to 80%; and the third powder at a content by weight lying in the rangeof 0.005% to 25%; and optionally, an anti-caking agent at a content byweight lying in the range of 0.05% to 10%.
 11. The method according toclaim 1, the therapeutic agent comprising an antiseptic agent, ananti-inflammatory agent, an anesthetic agent, a desensitizing agent, aremineralizing agent, an astringent agent, or a mixture of such agents.12. The method according to claim 1, wherein the composition is sprayedby a dental air polishing tool having a nozzle and a tank containing thecomposition, the composition being prayed through the nozzle underpressure surrounded by a jet of liquid.
 13. The method according toclaim 1, wherein the treatment is a therapeutic treatment of dentaltissue.